special casting processes with different competitive examination questions

1. Special Casting
By S K Mondal

2. Shell Moulding
 The sand is mixed with a thermosetting resin is
allowed to come in contact with a heated metal pattern
(2000C).
 A skin (shell) of about 3.5 mm of sand and plastic
mixture adhere to the pattern.
 Then the shell is removed from the pattern.
 The cope and drag shells are kept in a flask with
necessary backup material and the molten metal is
poured into the mold.

3.  Can produce complex parts.
 A good surface finish and good size tolerance
reduce the need for machining.
 Materials can be cast: CI, Al and Cu alloys.

4. Shell moulding process

5. Molding Sand in Shell Molding
 The molding sand is a mixture of fine grained quartz sand
and powdered bakelite.
 Cold coating and Hot coating methods are used for
coating the sand grains with bakelite.
 Cold coating: quartz sand is poured into the mixer and
then the solution of powdered bakelite in acetone and
ethyl aldehyde are added. (mixture is 92% quartz sand,
5% bakelite, 3% ethylaldehyde )
Contd…

6.  Hot coating: the mixture is heated to 150oC– 180oC prior
to loading the sand. In the course of sand mixing, the
soluble phenol formaldehyde resin is added. The mixer is
allowed to cool up to 80 – 90o C. Hot coting gives better
properties to the mixtures than cold method.

7. Advantages
 Dimensional accuracy.
 Smoother surface finish. (Due to finer size grain used)
 Very thin sections can be cast.
 Very small amount of sand is needed.

8. Limitations
 Expensive pattern
 Small size casting only.
 Highly complicated shapes cannot be obtained.
 More sophisticated equipment is needed for handling
the shell moldings.

9. Applications
 Cylinders and cylinder heads for air- cooled IC
engines
 Automobile transmission parts.
 Piston rings

10. IES-2005
In shell moulding, how can the shell thickness
be accurately maintained?
(a) By controlling the time during which the pattern
is in contact with mould
(b) By controlling the time during which the pattern
is heated
(c) By maintaining the temperature of the pattern in
the range of 175oC – 380oC
(d) By the type of binder used

11. IAS-2007
The mould in shell moulding process is made up
of which of the following?
(a) Gypsum + setting agents
(b) Green sand + clay
(c) Sodium silicate + dried sand
(d) Dried silica + phenolic resin

12. Investment Casting
Investment casting process or lost wax process
Basic steps:
1. Produce expendable wax, plastic, or polystyrene patterns.
2. Assemble these patterns onto a gating system
3. Investing or covering the pattern assembly with refractory
slurry
4.Melting the pattern assembly to remove the pattern material
5. Firing the mould to remove the last traces of the pattern
material
6.Pouring molten metal
7. Knockout, cutoff and finishing.

13. Fig. Investment flask-casting procedure

15. Ceramic Shell Investment Casting
 In ceramic shell investment casting a ceramic shell is
built around a tree assembly by repeatedly dipping a
pattern into a slurry (refractory material such as
zircon with binder).
 After each dipping and stuccoing is completed, the
assembly is allowed to thoroughly dry before the next
coating is applied.

17. IES 2009
 2 marks

18. Advantages
 Tight dimensional tolerances
 Excellent surface finish (1.2 to 3.0 m )
 Machining can be reduced or completely
eliminated
 High melting point alloy can be cast, almost any
metal can be cast
 Almost unlimited intricacy

19. Limitations
 Costly patterns and moulds
 Labour costs can be high
 Limited size

20. Applications
 Aerospace and rocket components.
 Vanes and blades for gas turbines.
 Surgical instruments

21. IES 2011
The proper sequence of investment casting steps is :
(a) Slurry coating – pattern melt out-Shakeout – Stucco
coating
(b) Stucco coating – Slurry coating – Shakeout – Pattern
melt out
(c) Slurry coating – Stucco coating – Pattern melt out –
Shakeout
(d) Stucco coating – Shakeout – Slurry coating – Pattern
melt out

22. IAS-1996
Light and intricate parts with close dimensional
tolerances of the order of ± 0.005 mm are
produced by
(a) Investment casting
(b) Die casting
(c) Centrifugal casting
(d) Shell mould casting

23. Permanent Mould Casting
 The process in which we use a die to make the
castings is called permanent mold casting or gravity
die casting, since the metal enters the mold under
gravity.
 Some time in die-casting we inject the molten metal
with a high pressure. When we apply pressure in
injecting the metal it is called pressure die casting
process.
 Grey cast iron is used for mould material.

24. Advantages
 Good surface finish and dimensional accuracy
 Metal mold gives rapid cooling and fine-grain
structure
 Multiple-use molds.

25. Disadvantages
 High initial mold cost
 Shape, size, and complexity are limited
 Mold life is very limited with high-melting-point
metals such as steel.
 Low melting point metals can be cast
- Aluminum
- Zinc
- Magnesium alloys
- Brass
- Cast iron

26. Applications
 Pistons/cylinders/rods
 Gears
 Kitchenware

27. Die Casting
 Molten metal is injected into closed metal dies under
pressures ranging from 100 to 150 MPa.
 Pressure is maintained during solidification
 After which the dies separate and the casting is ejected
along with its attached sprues and runners.
 Cores must be simple and retractable and take the
form of moving metal segments

28. Video

29. Die casting machines can be
Hot chamber
Cold chamber

30. Hot chamber machines are
 Good for low temperature (approx. 400°C)
 Faster than cold chamber machines
 Cycle times must be short to minimize metal
contamination
 Metal starts in a heated cylinder
 A piston forces metal into the die
 The piston retracts, and draws metal in
 Metal: Lead, Tin, Zinc

31. Hot Chamber

32. Cold chamber machines
 Casts high melting point metals ( > 600°C)
 High pressures used
 Metal is heated in a separate crucible
 Metal is ladled into a cold chamber
 The metal is rapidly forced into the mold before it
cools
 Copper, Brass and Aluminium can cast.

35. Advantages
 Extremely smooth surfaces (1 µm)
 Excellent dimensional accuracy
 Rapid production rate
 Better mechanical properties compared to sand
casting
 Intricate parts possible
 Minimum finishing operations
 Thin sections possible

36. Limitations
 High initial die cost
 Limited to high-fluidity nonferrous metals
 Part size is limited
 Porosity may be a problem
 Some scrap in sprues, runners, and flash, but this can
be directly recycled

37. Applications
 Carburettors
 Automotive parts
 Bathroom fixtures
 Toys
Common metals
 Alloys of aluminum, zinc, magnesium, and lead
 Also possible with alloys of copper and tin

38. IES 2011
Consider the following advantages of die casting over
sand casting :
1. Rapidity of the process
2. Smooth surface
3. Strong dense metal structure
Which of these advantages are correct ?
(a) 1, 2 and 3
(b) 1 and 2 only
(c) 2 and 3 only
(d) 1 and 3 only

39. IAS-2007
Consider the following statements:
1. Zinc die castings have low strength.
2. In the die casting process, very thin sections or
complex shapes can be obtained easily.
Which of the statements given above is/are correct?
(a) 1 only
(b) 2 only
(c) Both 1 and 2
(d) Neither 1 nor 2

40. IES 2011
Consider the following statements :
1. Hot chamber machine is used for casting zinc, tin and
other low melting alloys.
2. Cold chamber machine is used for die casting of
ferrous alloys
3. Rapid cooling rate in die casting produces high
strength and quality in many alloys.
Which of these statements are correct?
(a) 1, 2 and 3 (b) 1 and 2 only
(c) 2 and 3 only (d) 1 and 3 only

41. Centrifugal Casting
 Process: Molten metal is introduced into a rotating sand,
metal, or graphite mould, and held against the mould
wall by centrifugal force until it is solidified
 A mold is set up and rotated along a vertical (rpm is
reasonable), or horizontal (200-1000 rpm is reasonable)
axis.
 The mold is coated with a refractory coating.
 During cooling lower density impurities will tend to rise
towards the center of rotation.

42. Fig. True centrifugal casting

44. Properties
 The mechanical properties of centrifugally cast jobs are
better compared to other processes, because the inclusions
such as slag and oxides get segregated towards the centre
and can be easily removed by machining. Also, the
pressure acting on the metal throughout the solidification
causes the porosity to be eliminated giving rise to dense
metal.
 No cores are required for making concentric holes in the
case of true centrifugal casting.

45. Advantages
 Fine grained structure at the outer surface of the
casting free of gas and shrinkage cavities and
porosity
 Formation of hollow interiors in cylinders without
cores
 Can produce a wide range of cylindrical parts,
including ones of large size.
 Good dimensional accuracy, soundness, and
cleanliness
 There is no need for gates and runners, which
increases the casting yield, reaching almost 100 %.

46. Limitations
 More segregation of alloy component during pouring under
the forces of rotation
 Contamination of internal surface of castings with non-
metallic inclusions
 Inaccurate internal diameter
 Shape is limited.
 Spinning equipment can be expensive
 Poor machinability

47. Common metals
 Iron
 steel
 stainless steel
 alloys of aluminium, copper, and nickel

48. GATE -2008 (PI)
In hollow cylindrical parts, made by centrifugal casting,
the density of the part is
(a) maximum at the outer region
(b) maximum at the inner region
(c) maximum at the mid-point between outer and inner
surfaces
(d) uniform throughout

49. IES-2009
Which of the following are the most likely
characteristics in centrifugal casting?
(a) Fine grain size and high porosity
(b) Coarse grain size and high porosity
(c) Fine grain size and high density
(d) Coarse grain size and high density

50. Semi-centrifugal Casting
 Centrifugal force assists the flow of metal from a
central reservoir to the extremities of a rotating
symmetrical mold, which may be either expendable or
multiple-use
 Rotational speeds are lower than for true centrifugal
casting
 Cores can be used to increase the complexity of the
product.

51. Fig. Semi-centrifugal casting

52. Centrifuging
 Uses centrifuging action to force the metal from a central
pouring reservoir into separate mold cavities that are
offset from the axis of rotation.
 Low speed
 May used to assist in the pouring of investment casting
trees.

53. Fig. Method of casting by the centrifuging process

54. Dry Sand Molding
 To reduce gas forming materials air dried mould used.
Types:
1.Skin drying and
2.Complete mold drying

55. Slush Casting
 Slush casting is a variation of the permanent mold process
in which the metal is permitted to remain in the mold only
until a shell of the desired thickness has formed.
 The mold is then inverted and the remaining liquid is
poured out.
 When the mold halves are separated, the resulting casting
is a hollow shape with good surface detail but variable wall
thickness.
 Frequently used to cast low-melting-temperature metals
into ornamental objects such as candlesticks, lamp bases,
and statuary.

56. IES 2011
The method of casting for producing ornamental pieces
are:
(a) Slush and gravity casting
(b) Pressed and slush casting
(c) Gravity and semi permanent mould casting
(d) Semi permanent mould and pressed casting

57. IES - 2012
The process of making hollow castings of non-circular
shape and desired thickness by permanent mould
without the use of cores is known as
(a) Die casting (b) Slush casting
(c) Pressed casting (d) Centrifugal casting

58. Squeeze Casting
Process:
1. Molten metal is poured into an open face die.
2. A punch is advanced into the die, and to the metal.
3.Pressure (less than forging) is applied to the punch
and die while the part solidifies.
4.The punch is retracted, and the part is knocked out
with an ejector pin.
 Overcomes problems with feeding the die, and
produces near net, highly detailed parts.

59. Single Crystal Casting
The process is effectively:
1. Prepare a mold so that one end is a heated oven, and
the other end chilled. The part should be oriented so
that the cooling happens over the longest distance.
2. Cast metal into the mold
3. Solidification will begin at the chill plate. These
dendrites will grow towards the heated end of the
part as long dendritic crystals. The part is slowly
pulled out of the oven, past the chill plate.
4. Remove the solidified part.

60.  Creep and thermal shock resistance properties.

61. IES 2009
2 marks

62. Plaster Casting
 Process: A slurry of plaster, water, and various additives is
additives is pouted over a pattern and allowed to set. The
pattern is removed and the mould is baked to remove
excess water. After pouring and solidification, the mould is
broken and the casting is removed.
 Advantage: High dimensional accuracy and smooth
surface finish, thin sections and intricate detail can
produce.
 Limitations: Lower-temperature nonferrous metals only:
 Common metals: Primarily aluminium and copper

63. Pit Moulding
 This method is used for very large castings and is done on
the foundry floor.

64. IES-1996
Which of the following pairs are correctly matched?
1. Pit moulding ..................For large jobs.
2. Investment moulding ... Lost wax process.
3. Plaster moulding ……… Mould prepared in
gypsum.
(a) 1, 2 and 3 (b) 1 and 2
(c) 1 and 3 (d) 2 and 3

65. Loam Moulding
 Moulding loam is generally artificially composed of
common brick-clay, and sharp sand.
 Loam means mud.
 Loam Moulding is restricted to forms which cannot be
cast conveniently in any other process.
 It is costly.

66. IES-1997
Which one of the following pairs is not correctly
matched?
(a) Aluminium alloy piston …………Pressure die casting
(b) Jewellery……………………….. Lost wax process
(c) Large pipes ……………………..Centrifugal casting
(d) Large bells ………………………Loam moulding

67. GATE-1998
List I List II
(A) Sand casting (1) Symmetrical and
circular shapes only
(B) Plaster mould casting (2) Parts have hardened
skins and soft interior
(C) Shell mould casting (3) Minimum post-
casting processing
(D) Investment casting (4) Parts have a tendency
to warp
(5) Parts have soft skin
and hard interior
(6) Suitable only for non-
ferrous metals

69. Q. No Option
1 A
2 A
3 C
4 A
5 D
6 A
7 D
8 C
9 B
10 D
11 A
12 B
Q. No Option
13 C
14 D
15 D
16 B
17 B
18 B
19 D
20 A
21 A
Conventional Casting Process Ch-21

70. Q. No Option
1 D
2 C
3 C
4 B
5 C
6 A
7 D
8 C
9 B
10 D
Q. No Option
11 A
12 A
13 D
14 A
15 A
16 B
17 A
Special Casting Process Ch-22